Methods for enhancing myogenic and/or chondrogenic lineage commitment of stem cells, inhibiting adipogenic differentiation of stem cells, and for promoting tissue regeneration using fibroblast growth factor 8 (FGF8).

The present invention relates generally to the field of long non-coding RNAs and transcription factors and modulation of their expression for use in medicine and agriculture, such as the treatment and prevention of diseases associated with muscle atrophy and the production of livestock. More particularly, the invention provides agonists of Cytor, a long non-coding RNA, e.g. agents that increase the amount of Cytor RNA in skeletal muscle as well as antagonists for Teadl, a transcription factor, e.g. agents that decrease the amount of Teadl RNA or protein in skeletal muscle and their use in therapy.

In related-art methods of differentiating pluripotent stem cells into a desired cell type, there has not been established a differentiation induction method using human ES/iPS cells and being stable and highly efficient. The use of complicated culture steps is a large problem. In addition, there are also large problems in, for example, that the speed of cell differentiation is low, and hence long-period culture is required, and that the differentiation efficiency is low, and hence it is difficult to obtain a sufficient number of required cells. A method of inducing differentiation into a desired cell type, which induces differentiation within a short period of time and with high efficiency by the use of a Sendai virus vector capable of expressing a transcription factor, and as required, the use of a pluripotent stem cell in which an expression amount of a POU5F1 protein has been substantially removed or reduced, is provided.

A method is described for enhancing arteriogenesis in animals with comorbidities commonly found in patients with ischemic disease, and in animals with a genetically-impaired arteriogenesis response. Administration to an animal of satellite derived myoblasts increases maximum diameter of collateral arteries. In embodiments, the animal is an obese animal or an animal having impaired arteriogenesis due to genetic variation causing the phenotype. The administration of such myoblasts to a non-obese animal does not increase maximum diameter of the animal's collateral arteries. Blood flow is increased, and ischemia is decreased. Compositions and kits comprising the myoblasts are also provided.

In related-art methods of differentiating pluripotent stem cells into a desired cell type, there has not been established a differentiation induction method using human ES/iPS cells and being stable and highly efficient. The use of complicated culture steps is a large problem. In addition, there are also large problems in, for example, that the speed of cell differentiation is low, and hence long-period culture is required, and that the differentiation efficiency is low, and hence it is difficult to obtain a sufficient number of required cells. A method of inducing differentiation into a desired cell type, which induces differentiation within a short period of time and with high efficiency by the use of a Sendai virus vector capable of expressing a transcription factor, and as required, the use of a pluripotent stem cell in which an expression amount of a POU5F1 protein has been substantially removed or reduced, is provided.

The present invention relates to a composition for inducing cell reprogramming. The indazole derivative compound contained in the composition of the present invention shows an improved biological profile and at the same time can perform efficient cell reprogramming. In addition, unlike conventional compounds (e.g. riversine or BIO) for inducing low-molecular cell reprogramming, the indazole derivative compound of the present invention does not show cytotoxicity and thus is expected to have high growth in the market of cell therapy products when clinically applied. Conventional indazole derivative compounds have never known as a use for cell reprogramming. Compared with conventional indazole derivative compounds, the compound of the present invention has a great cell reprogramming ability while having no or little cytotoxicity.

The present invention relates to a method for reprogramming a first cell type to an intermediate cell of a second cell type comprising the step of contacting the first cell with a first agent to modulate an integrin profile in the first cell type to provide an intermediate cell of the second cell type. The present invention also relates to a reprogrammed cell obtained by the method of the invention, a kit for reprogramming a first cell type to a second cell type as well as methods for treating a patient in need of cell based therapy, tissue replacement and cancer therapy.

A method for co-cultivation and directed differentiation induction of muscle satellite cells and adipose-derived stem cells is provided. The method includes the steps of co-cultivation and co-differentiation. The method for co-cultivation and directed differentiation induction of muscle satellite cells and adipose-derived stem cells provided by the present disclosure can allow the effective co-cultivation and co-directed differentiation induction of muscle satellite cells and adipose-derived stem cells from Larimichthys crocea, thereby providing a feasible solution for the large-scale production of high-quality cultivated meat.

The present invention relates to methods for obtaining induced smooth muscle cells (iSMCs), iSMCs, iSMCs for use in a method of treating a disease or disorder or for use in tissue engineering, and the use of skeletal muscle derived cells for obtaining iSMCs.

The present invention relates to methods for obtaining induced smooth muscle cells (iSMCs), iSMCs, iSMCs for use in a method of treating a disease or disorder or for use in tissue engineering, and the use of skeletal muscle derived cells for obtaining iSMCs.